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Collaboration Between Agilent and DESY Created a New Kind of Ion Getter Pump

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Collaboration Between Agilent and DESY Created a New Kind of Ion Getter Pump Agilent case study: Research—Accelerated Collaboration Between Agilent and DESY Created a New Kind of Ion Getter Pump When researchers come to Hamburg to see the particle accelerators at DESY, they have a lot of questions. Questions about the interactions of tiny elementary particles. Questions about the behavior of new types of nanomaterials. Questions that will take time and testing to answer. But one of the most common questions they ask is simply, “What is this?” The object of their curiosity is actually a series of objects attached, every 6 m, on the accelerator of the European XFEL, the world’s largest X-ray laser, that stretches out before them for more than 3 km. Torsten Wohlenberg “They always ask because it looks very peculiar,” says Winfried Decking, Engineer scientist and coordinator for accelerator construction at DESY, a leading MVS DESY research center with 50 years of experience building and operating accelerators. The Pump and the System Decking, a physicist, is referring to the unique design of the in-line ion getter pumps that he and his colleague, Torsten Wohlenberg, an engineer, helped to develop in collaboration with Agilent. (The cross-functional team from Agilent included R&D, marketing, and order-fulfilment personnel.) “Our idea was to design a pump directly around the beam pipe,” Wohlenberg says. Compared to traditional designs, which use T-pieces to connect pumps to the pipe, the in-line pump is far easier to install. Indeed, the core of the in-line Winfried Decking pump—manufactured to precise dimensions and strict tolerances—becomes part of the pipe through which the beam passes. Physicist MXL DESY “It has other benefits from more of a physics point of view,” Wohlenberg explains, “because it has a very low magnetic field where the beam passes through, which is very beneficial for the high-quality beams we are using.” “We are very happy with the results,” Decking adds. “Of course, it’s not one pump. We are talking about a system, a huge-scale vacuum system based on these pumps—and they work very, very nicely.” Designing Away Drawbacks In a particle accelerator, a beam of charged particles travels in an environment that is maintained under high vacuum In-line ion getter pump developed for the particle conditions. To achieve the desired degree of vacuum, accelerator at DESY scientists use ion getter pumps, which are highly reliable and do not generate vibrations that could disturb the trajectory of Other Advantages the beam. “One requirement we had for this 3 km vacuum system was that it should be aligned very precisely, locally to 0.1 mm Traditional configurations, however, are affected by two in some parts. To do that, you need fixed points, and these drawbacks: points are the vacuum pumps. They are positioned very • Accelerated particles are sensitive to stray magnetic precisely, and are aligned as any other accelerator component, fields, specifically to the influence of components such as magnets and so on,” Wohlenberg says. transverse to the direction of the beam. In a typical “When you have an accelerator and you shoot an electron configuration, the magnets are asymmetrically related beam through it, you want to know where the beam is in this to the beam tube, thus preventing a self-compensating vacuum pipe. For this, we need beam-position monitors, effect of the components. which also should be very, very precise, again, to 0.1 or • The beam of charged particles must be protected from 0.2 mm. Because it is so easy and so nice to set these the titanium sputtered by the ion pump cathodes and also vacuum pumps, we just attach the beam-position monitors from titanium debris from possible peeling phenomena. rigidly to the pumps as a real unit, and align them together. This issue is typically overcome with the addition of This was something that was not foreseen at the beginning, complex optical shields, which reduce the effective but turned out to be a very efficient solution when you need to pumping speed. install a couple of hundred of these beam-position monitors together with the vacuum pumps. That is something we The in-line design offers a number of advantages. The found unique, so our standard modular unit is a pump and arrangement of the magnets and the geometry of the pole beam-position monitor as a fixed point for the vacuum piece used to guide the magnetic field lines were conceived to system. The main point is that the installation is much minimize any disturbance to the beam’s trajectory. Moreover, easier. If you have to install this huge number of pumps, then the element location inside the pump has been optimized to installing them easy or not easy makes a huge difference.” be optically self-shielded toward the beam, without requiring additional expensive and complex optical shields. Finally, Agilent offers an array of robust, industry-leading high vacuum thanks to the in-line solution, a simple RF shield (a copper pumping systems for a range of applications. For more coated tube with pumping slits) can easily be installed directly information, visit https://www.agilent.com/en-us/products/ inside the pump at the accelerator site. vacuum-technologies, and https://www.agilent.com/en/ promotions/vacuum-beyond-specifications www.agilent.com This information is subject to change without notice. © Agilent Technologies, Inc. 2017 Published in the USA, November 20, 2017 5991-8733EN.
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